Handling of constraints in multiobjective blackbox optimization

IF 1.6 2区数学 Q2 MATHEMATICS, APPLIED Computational Optimization and Applications Pub Date : 2024-07-16 DOI:10.1007/s10589-024-00588-2

Jean Bigeon, Sébastien Le Digabel, Ludovic Salomon

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Abstract

This work proposes the integration of two new constraint-handling approaches into the blackbox constrained multiobjective optimization algorithm DMulti-MADS, an extension of the Mesh Adaptive Direct Search (MADS) algorithm for single-objective constrained optimization. The constraints are aggregated into a single constraint violation function which is used either in a two-phase approach, where the search for a feasible point is prioritized if not available before improving the current solution set, or in a progressive barrier approach, where any trial point whose constraint violation function values are above a threshold are rejected. This threshold is progressively decreased along the iterations. As in the single-objective case, it is proved that these two variants generate feasible and/or infeasible sequences which converge either in the feasible case to a set of local Pareto optimal points or in the infeasible case to Clarke stationary points according to the constraint violation function. Computational experiments show that these two approaches are competitive with other state-of-the-art algorithms.

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多目标黑箱优化中的约束处理

本研究提出将两种新的约束处理方法整合到黑盒约束多目标优化算法 DMulti-MADS 中，DMulti-MADS 是用于单目标约束优化的网格自适应直接搜索（MADS）算法的扩展。约束条件被汇总为一个单一的约束违规函数，该函数可用于两阶段方法，即在改进当前解集之前，如果没有可行点，则优先搜索可行点；或用于渐进障碍方法，即拒绝约束违规函数值高于阈值的任何试验点。在迭代过程中，阈值会逐渐降低。正如在单目标情况下一样，实验证明这两种方法都能产生可行和/或不可行序列，在可行情况下，这些序列会收敛到一组局部帕累托最优点，在不可行情况下，会根据违反约束函数收敛到克拉克静止点。计算实验表明，这两种方法与其他最先进的算法相比具有竞争力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Computational Optimization and Applications 数学-应用数学

CiteScore

3.70

自引率

9.10%

发文量

审稿时长

10 months

期刊介绍： Computational Optimization and Applications is a peer reviewed journal that is committed to timely publication of research and tutorial papers on the analysis and development of computational algorithms and modeling technology for optimization. Algorithms either for general classes of optimization problems or for more specific applied problems are of interest. Stochastic algorithms as well as deterministic algorithms will be considered. Papers that can provide both theoretical analysis, along with carefully designed computational experiments, are particularly welcome. Topics of interest include, but are not limited to the following: Large Scale Optimization, Unconstrained Optimization, Linear Programming, Quadratic Programming Complementarity Problems, and Variational Inequalities, Constrained Optimization, Nondifferentiable Optimization, Integer Programming, Combinatorial Optimization, Stochastic Optimization, Multiobjective Optimization, Network Optimization, Complexity Theory, Approximations and Error Analysis, Parametric Programming and Sensitivity Analysis, Parallel Computing, Distributed Computing, and Vector Processing, Software, Benchmarks, Numerical Experimentation and Comparisons, Modelling Languages and Systems for Optimization, Automatic Differentiation, Applications in Engineering, Finance, Optimal Control, Optimal Design, Operations Research, Transportation, Economics, Communications, Manufacturing, and Management Science.